Long-time efficacy of the surface code in the presence of a superohmic environment

TL;DR

This paper analyzes the long-term stability of a quantum memory using the surface code when coupled to a superohmic environment, revealing a phase transition that determines the threshold for preserving quantum information.

Contribution

It provides an analytical mapping of the quantum memory evolution to a spin system, identifying critical parameters for memory preservation in superohmic environments.

Findings

Long-time evolution matches single QEC cycle behavior in superohmic case.

Derived critical parameters for phase transition in the equivalent spin system.

Established threshold for system-environment coupling to maintain quantum memory.

Abstract

We study the long-time evolution of a quantum memory coupled to a bosonic environment on which quantum error correction (QEC) is performed using the surface code. The memory's evolution encompasses $N$ QEC cycles, each of them yielding a non-error syndrome. This assumption makes our analysis independent of the recovery process. We map the expression for the time evolution of the memory onto the partition function of an equivalent statistical mechanical spin system. In the superohmic dissipation case the long-time evolution of the memory has the same behavior as the time evolution for just one QEC cycle. For this case we find analytical expressions for the critical parameters of the order-disorder phase transition of an equivalent spin system. These critical parameters determine the threshold value for the system-environment coupling below which it is possible to preserve the memory's state.